In a semiconductor device, an active region includes: a first impurity region to which a predetermined voltage is applied; second and third impurity regions forming a pair of conductive electrodes of an insulated gate field effect transistor; and at least one impurity region disposed between the first and second impurity regions. A voltage that causes electrical conduction between the second and third impurity regions is applied to a gate electrode disposed between the second and third impurity regions. All gate electrodes disposed between the first and second impurity regions are configured to be electrically connected to the first impurity region constantly. All impurity regions disposed between the first and second impurity regions are electrically isolated from the first and second impurity regions and maintained in a floating state.
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1. A semiconductor device, comprising:
an active region formed on a main surface of a semiconductor substrate and including a plurality of impurity regions of the same conductivity type arranged one-dimensionally; and
a plurality of gate electrodes, each of which is provided individually in each region between two adjacent impurity regions of said plurality of impurity regions when the main surface of said semiconductor substrate is seen in a plan view, and each of which forms an insulated gate field effect transistor together with the two adjacent impurity regions,
wherein said plurality of impurity regions include:
a first impurity region to which a predetermined voltage is applied,
second and third impurity regions forming a pair of conductive electrodes of an insulated gate field effect transistor,
fourth and fifth impurity regions, one of which forms a source electrode of a different insulated gate field effect transistor, and the other of which forms a drain electrode of the different insulated gate field effect transistor, and
at least one impurity region disposed between said first and fourth impurity regions,
wherein a voltage that causes electrical conduction between said second and third impurity regions is applied to a gate electrode, disposed between said second and third impurity regions, of said plurality of gate electrodes,
wherein a voltage that causes electrical conduction between said fourth and fifth impurity regions is applied to a gate electrode, disposed between said fourth and fifth impurity regions, of said plurality of gate electrodes,
wherein all gate electrodes disposed between said first and fourth impurity regions, of said plurality of gate electrodes, are configured to be electrically connected to said first impurity region constantly, and
wherein, by application of said predetermined voltage to all gate electrodes disposed between said first and fourth impurity regions, all impurity regions disposed between said first and fourth impurity regions, of said plurality of impurity regions, are electrically isolated from said first and fourth impurity regions and maintained in a floating state.
8. A semiconductor device, comprising:
an active region formed on a main surface of a semiconductor substrate and including a plurality of impurity regions of the same conductivity type arranged one-dimensionally;
a plurality of gate electrodes, each of which is provided individually in each region between two adjacent impurity regions of said plurality of impurity regions when the main surface of said semiconductor substrate is seen in a plan view, and each of which forms an insulated gate field effect transistor together with the two adjacent impurity regions; and
a different active region formed on the main surface of said semiconductor substrate, including a plurality of impurity regions of the same conductivity type arranged one-dimensionally, and isolated from said active region by a shallow trench isolation,
wherein said plurality of impurity regions include:
a first impurity region to which a predetermined voltage is applied,
second and third impurity regions forming a pair of conductive electrodes of an insulated gate field effect transistor, and
at least one impurity region disposed between said first and second impurity regions,
wherein a voltage that causes electrical conduction between said second and third impurity regions is applied to a gate electrode, disposed between said second and third impurity regions, of said plurality of gate electrodes,
wherein all gate electrodes disposed between said first and second impurity regions, of said plurality of gate electrodes, are configured to be electrically connected to said first impurity region constantly,
wherein by application of said predetermined voltage to all gate electrodes disposed between said first and second impurity regions, all impurity regions disposed between said first and second impurity regions, of said plurality of impurity regions, are electrically isolated from said first and second impurity regions and maintained in a floating state,
wherein said second impurity region is connected to an insulated gate field effect transistor different from the insulated gate field effect transistor formed by said second and third impurity regions, and
wherein said plurality of impurity regions of said different active region include a fourth impurity region electrically connected to said second impurity region and forming one of a pair of conductive electrodes of said different insulated gate field effect transistor.
2. The semiconductor device according to
a shallow trench isolation formed around said active region,
wherein said first impurity region is located at an end of one-dimensional arrangement formed by said plurality of impurity regions.
3. The semiconductor device according to
wherein a length of said second impurity region along an arrangement direction of said plurality of impurity regions is equal to a length, along said arrangement direction, of each of all impurity regions disposed between said first and second impurity regions, and
lengths, along said arrangement direction, of all gate electrodes disposed between said first impurity region and said third impurity region when the main surface of said semiconductor substrate is seen in a plan view are equal to one another.
4. The semiconductor device according to
wherein a length of said second impurity region along an arrangement direction of said plurality of impurity regions, a length of said fourth impurity region along said arrangement direction, and a length, along said arrangement direction, of each impurity region disposed between said second and fourth impurity regions and including said first impurity region are equal to one another, and
lengths, along said arrangement direction, of all gate electrodes disposed between said third and fifth impurity regions are equal to one another.
5. The semiconductor device according to
wherein said second impurity region is connected to an insulated gate field effect transistor different from the insulated gate field effect transistor formed by said second and third impurity regions.
6. The semiconductor device according to
wherein said plurality of impurity regions further include a fourth impurity region electrically connected to said second impurity region and forming one of a pair of conductive electrodes of said different insulated gate field effect transistor.
7. The semiconductor device according to
wherein said third impurity region forms the other conductive electrode of said different insulated gate field effect transistor.
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The present invention relates to a semiconductor device having a plurality of insulated gate field effect transistors integrated therein.
In a semiconductor device having a plurality of MOS (Metal Oxide Semiconductor) transistors integrated therein, a shallow trench isolation (STI) is used for element isolation. Since silicon used in an active region of an MOS transistor is different in thermal expansion coefficient from an oxide film used in the STI, stress is produced in an MOS transistor provided near the STI. With the progress of reduction in size of MOS transistors, fluctuations in properties of the MOS transistors caused by this STI stress have become a problem. Specifically, the mobility increases due to the STI stress (compressive stress) in the case of a P-type MOS transistor, while the mobility decreases due to the STI stress (compressive stress) in the case of an N-type MOS transistor (refer to, for example, R. A. Bianchi et al., “Accurate Modeling of Trench Isolation Induced Mechanical Stress effects on MOSFET Electrical Performance”, IEEE, IEDM Proc., pp. 117-120, 2002 (NPD 1)).
As a technique for reducing such STI strain, there has been known a technique disclosed in Japanese Patent Laying-Open No. 2008-288268 (PTD 1), for example. In a semiconductor integrated circuit described in this document, an off-state dummy transistor is disposed adjacent to an active region of an MOS transistor involved in circuit operation. As a result, stress strain to the MOS transistor is reduced.
In a technique disclosed in International Publication No. WO2009/037808 (PTD 2), a substrate contact line is disposed at an outer end of an active region that is on the outer side of the aforementioned dummy transistor, in order to further reduce the STI strain.
Japanese Patent Laying-Open No. 2006-286889 (PTD 3) discloses a technique of enhancing an operating current of an MOS transistor by actively using the STI strain. Specifically, an insulating material that provides compressive stress to an active region of a P-type MOS transistor is filled into a region adjacent to the P-type MOS transistor in a channel length direction thereof, of an STI element isolation region. An insulating material that provides tensile stress to the P-type and N-type MOS transistors is filled into the remaining element isolation region.
A technique of using the aforementioned off-state dummy transistor for element isolation of adjacent MOS transistors has been conventionally known (refer to, for example, Japanese Patent Laying-Open No. 4-125949 (PTD 4) and Japanese Patent Laying-Open No. 11-233640 (PTD 5)).
When the dummy transistor is provided to relieve the STI stress, an off-leakage current through the dummy transistor may become a problem in some cases. For example, in the case of an analog semiconductor circuit incorporated into a battery-driven mobile phone and the like, the off-leakage current that flows when the mobile phone is in a standby state becomes a problem. In the case of a flash-type AD (Analog-to-Digital) converter in which multiple comparators are disposed in parallel or a current cell-type DA (Digital-to-Analog) converter in which multiple current sources are used, multiple dummy transistors must be provided, and thus, an influence of the off-leakage current is significant.
One object of the present invention is to, in a semiconductor device provided with dummy transistors, reduce an off-leakage current flowing through the dummy transistors.
A semiconductor device according to an embodiment of the present invention includes: an active region; and a plurality of gate electrodes. The active region is formed on a main surface of a semiconductor substrate and includes a plurality of impurity regions of the same conductivity type arranged one-dimensionally. Each of the plurality of gate electrodes is provided individually in each region between two adjacent impurity regions of the plurality of impurity regions when the main surface of the semiconductor substrate is seen in a plan view. Each gate electrode forms an insulated gate field effect transistor together with the two adjacent impurity regions. The plurality of impurity regions include: a first impurity region to which a predetermined voltage is applied; second and third impurity regions forming a pair of conductive electrodes of an insulated gate field effect transistor; and at least one impurity region disposed between the first and second impurity regions. A voltage that causes electrical conduction between the second and third impurity regions is applied to a gate electrode disposed between the second and third impurity regions, of the plurality of gate electrodes. All gate electrodes disposed between the first and second impurity regions, of the plurality of gate electrodes, are configured to be electrically connected to the first impurity region constantly. By application of the predetermined voltage to all gate electrodes disposed between the first and second impurity regions, all impurity regions disposed between the first and second impurity regions, of the plurality of impurity regions, are electrically isolated from the first and second impurity regions and maintained in a floating state.
In the semiconductor device according to the embodiment described above, a plurality of off-state dummy transistors are serially disposed between the first impurity region to which a power supply voltage or ground voltage is applied and the second impurity region involved in circuit operation. Therefore, an off-leakage current flowing through the dummy transistors can be reduced.
Embodiments of the present invention will be described in detail hereinafter with reference to the drawings, in which the same reference characters are given to the same or corresponding portions and description thereof will not be repeated.
<First Embodiment>
[Example of Application to NMOS Transistor]
Impurity regions NI1 to NI6 and channel regions NC1 to NC6 as a whole are referred to as an active region AR1. A shallow trench isolation STI is formed around active region AR1. The shallow trench isolation refers to a portion formed by embedding an oxide film and the like in a shallow groove formed in a surface of a semiconductor substrate (silicon substrate) in order to isolate active regions in an insulating manner. Hereinafter, impurity regions NI1 to NI6, gate electrodes G1 to G5 and channel regions NC1 to NC5 are referred to as impurity region NI, gate electrode G and channel region NC, respectively, when they are collectively referred or when an unspecified one is indicated.
Each gate electrode G and two adjacent impurity regions NI form the NMOS transistor (more generally, insulated gate field effect transistor). In other words, two impurity regions NI adjacent to each gate electrode G form a pair of conductive electrodes of the NMOS transistor. More specific description will be given. Gate electrode G3 and adjacent impurity regions NI3 and NI4 form NMOS transistor MN1. Gate electrode G4 and adjacent impurity regions NI4 and NI5 form dummy transistor MND1. Gate electrode G5 and adjacent impurity regions N15 and N16 form dummy transistor MND2. Gate electrode G2 and adjacent impurity regions NI2 and NI3 form dummy transistor MND3. Gate electrode G1 and adjacent impurity regions NI1 and NI2 form dummy transistor MND4.
In NMOS transistor MN1, gate electrode G3 is connected to an upper-layer metal line (not shown) for supplying a gate voltage Vg through a contact hole formed in an interlayer insulating layer ID. Impurity region NI3 is connected to an upper-layer metal line (not shown) for supplying a source voltage Vs through a contact hole C2 formed in interlayer insulating layer ID. Impurity region NI4 is connected to an upper-layer metal line (not shown) for supplying a drain voltage Vd through a contact hole C3 formed in interlayer insulating layer ID. A current flowing through NMOS transistor MN1 changes in accordance with these gate voltage Vg, source voltage Vs and drain voltage Vd. In other words, in accordance with gate voltage Vg applied to gate electrode G3, conduction occurs between impurity regions NI3 and NI4.
In dummy transistors MND1 to MND4, gate electrodes G1, G2, G4, and G5 are formed integrally and thereby interconnected. These gate electrodes G1, G2, G4, and G5 are connected to an upper-layer metal line (not shown) for supplying a ground voltage GND through a contact hole formed in interlayer insulating layer ID. As a result, dummy transistors MND1 to MND4 are turned off. Gate electrodes G1, G2, G4, and G5 do not necessarily need to be formed integrally. Gate electrodes G1, G2, G4, and G5 may be separated from one another and formed of a polysilicon layer, and each gate electrode may be connected individually to the upper-layer metal line for supplying ground voltage GND.
Of impurity regions NI1 to NI6 arranged one-dimensionally, impurity regions NI1 and NI6 located at opposing ends are connected to the upper-layer metal line for supplying ground voltage GND through contact holes C1 and C4 formed in interlayer insulating layer ID, respectively. In other words, impurity regions NI1 and NI6 located at the opposing ends of the one-dimensional arrangement are configured to be electrically connected to gate electrodes G1, G2, G4, and G5 constantly. Ground voltage GND is applied to these impurity regions N11 and N16 as well as gate electrodes G1, G2, G4, and G5. Since each of impurity regions NI2 and NI5 is not connected to any upper-layer metal lines and ground voltage GND is constantly applied to the gate electrodes adjacent to both sides thereof, each of impurity regions NI2 and NI5 is maintained in a floating state.
According to the semiconductor device having the above-described configuration, a distance from gate electrode G3 of NMOS transistor MN1 to the end of active region AR1 along a gate length direction (direction of arrangement of impurity regions NI1 to NI6) can be extended by dummy transistors MND1, MND2, MND3, and MND4. As a result, an influence of the STI stress on the properties of NMOS transistor MN1 can be reduced.
Furthermore, since two dummy transistors are serially connected between the node (source S1, drain D1) set at a voltage value other than ground voltage GND and the ground node, the off-leakage current can be reduced. The number of serially-connected dummy transistors may be further increased in order to further reduce the off-leakage current. When three dummy transistors are serially connected, for example, two floating-state impurity regions are disposed between the impurity region used as NMOS transistor MN1 in
Dummy transistors MND1, MND2, MND3, and MND4 also have the effect of suppressing the shape nonuniformity caused by the manufacturing process. Referring to
[Example of Application to PMOS Transistor]
Each gate electrode G and two adjacent impurity regions PI form the PMOS transistor. In other words, the two impurity regions adjacent to each gate electrode G form a pair of conductive electrodes of the PMOS transistor. Specifically, gate electrode G3 and adjacent impurity regions PI3 and PI4 form PMOS transistor MP1. Gate electrode G4 and adjacent impurity regions PI4 and PI5 form dummy transistor MPD1. Gate electrode G5 and adjacent impurity regions PI5 and PI6 form dummy transistor MPD2. Gate electrode G2 and adjacent impurity regions PI2 and PI3 form dummy transistor MPD3. Gate electrode G1 and adjacent impurity regions PI1 and PI2 form dummy transistor MPD4.
In PMOS transistor MP1, gate electrode G3 is connected to an upper-layer metal line (not shown) for supplying a gate voltage Vg through a contact hole formed in an interlayer insulating layer ID. Impurity region PI3 is connected to an upper-layer metal line (not shown) for supplying a source voltage Vs through a contact hole C2 formed in interlayer insulating layer ID. Impurity region PI4 is connected to an upper-layer metal line (not shown) for supplying a drain voltage Vd through a contact hole C3 formed in interlayer insulating layer ID. A current flowing through PMOS transistor WW1 changes in accordance with these gate voltage Vg, source voltage Vs and drain voltage Vd. In other words, in accordance with gate voltage Vg applied to gate electrode G3, conduction occurs between impurity regions PI3 and PI4.
In dummy transistors MPD1 to MPD4, gate electrodes G1, G2, G4, and G5 are formed integrally and thereby interconnected. These gate electrodes G1, G2, G4, and G5 are connected to an upper-layer metal line (not shown) for supplying a power supply voltage VDD through a contact hole formed in interlayer insulating layer ID. As a result, dummy transistors MPD1 to MPD4 are turned off. Gate electrodes G1, G2, G4, and G5 do not necessarily need to be formed integrally. Gate electrodes G1, G2, G4, and G5 may be separated from one another and formed of a polysilicon layer, and each gate electrode may be connected individually to the upper-layer metal line for supplying power supply voltage VDD.
Of impurity regions PI1 to PI6 arranged one-dimensionally, impurity regions PI1 and PI6 located at opposing ends are connected to the upper-layer metal line for supplying power supply voltage VDD through contact holes C1 and C4 formed in interlayer insulating layer ID, respectively. In other words, impurity regions P11 and PI6 located at the opposing ends of the one-dimensional arrangement are configured to be electrically connected to gate electrodes G1, G2, G4, and G5 constantly. Power supply voltage VDD is applied to these impurity regions PI1 and PI6 as well as gate electrodes G1, G2, G4, and G5. Since each of impurity regions PI2 and PI5 is not connected to any upper-layer metal lines and power supply voltage VDD is constantly applied to the gate electrodes adjacent to both sides thereof, each of impurity regions PI2 and PI5 is maintained in a floating state.
The effects of the above-described semiconductor device are similar to those of the NMOS transistor described with reference to
Furthermore, according to the above-described semiconductor device, the shape nonuniformity caused by the manufacturing process can be suppressed. Referring to
[Example of Application to Differential Amplifier]
Referring to
PMOS transistor MP11 and NMOS transistor MN12 are serially connected in this order between a power supply node to which power supply voltage VDD is supplied and a connection node ND1. PMOS transistor MP12 and NMOS transistor MN13 are serially connected in this order between a power supply node and connection node ND1. NMOS transistor MN11 is connected between connection node ND1 and a ground node to which ground voltage GND is supplied. Predetermined bias voltages Vb1, Vb2 and Vb3 are supplied to a gate electrode of NMOS transistor MN11 and gate electrodes of PMOS transistors MP11 and MP12, respectively. Differential signals (Vinp, Vinn) are inputted to gate electrodes of NMOS transistors MN12 and MN13 forming the differential pair. Amplified differential signals (Voutp, Voutn) are outputted from drains of these NMOS transistors MN13 and MN12. Resistor elements may be used instead of PMOS transistors MP11 and MP12.
In order to achieve the operation with low power consumption, it is desirable to set power supply voltage VDD to be as low as possible. Particularly when the differential amplifier in
When the NMOS transistors having different threshold voltages are present as described above, it is difficult to fabricate the NMOS transistors having different threshold voltages in the same active region. Therefore, in layout design of the differential amplifier shown in
(Layout of NMOS Transistors MN12 and MN13)
Referring to
Gate electrodes G11 and G12 are formed integrally and thereby interconnected, and are connected to upper-layer metal line MLA for supplying ground voltage GND through a contact hole formed in an interlayer insulating layer ID. Gate electrodes G17 and G18 are formed integrally and thereby interconnected, and are connected to upper-layer metal line MLA for supplying ground voltage GND through a contact hole formed in interlayer insulating layer ID. As a result, dummy transistors MND11 to MND14 are turned off. Gate electrodes G11 and G12 may be separated from each other and formed of a polysilicon layer, or gate electrodes G17 and G18 may be separated from each other and formed of a polysilicon layer. In this case, each of gate electrodes G11, G12, G17, and G18 is connected individually to upper-layer metal line MLA through the contact hole formed in interlayer insulating layer ID.
Gate electrodes G13 and G14 forming the two-finger gate are formed integrally and thereby interconnected, and are connected to an upper-layer metal line (not shown) for voltage signal Vinp through a contact hole formed in interlayer insulating layer ID. Similarly, gate electrodes G15 and G16 forming the two-finger gate are formed integrally and thereby interconnected, and are connected to an upper-layer metal line (not shown) for voltage signal Vinn through a contact hole formed in interlayer insulating layer ID. Gate electrodes G13 and G14 may be separated from each other and formed of a polysilicon layer, or gate electrodes G15 and G16 may be separated from each other and formed of a polysilicon layer. In this case, each of gate electrodes G13 and G14 is connected individually to the upper-layer metal line (not shown) for voltage signal Vinp. Similarly, each of gate electrodes G17 and G18 is connected individually to the upper-layer metal line (not shown) for voltage signal Vinn.
Impurity regions NM and NI19 located at opposing ends of the one-dimensional arrangement are connected to upper-layer metal line MLA for supplying ground voltage GND through contact holes C11 and C17 formed in interlayer insulating layer ID, respectively. In other words, impurity regions NI11 and NI19 located at the opposing ends of the one-dimensional arrangement are configured to be electrically connected to gate electrodes G11, G12, G17, and G18 constantly. Ground voltage GND is applied to these impurity regions NM and NI19 as well as gate electrodes G11, G12, G17, and G18. Since each of impurity regions NI12 and NI18 is not connected to any upper-layer metal lines and ground voltage GND is constantly applied to the gate electrodes adjacent to both sides thereof, each of impurity regions NI12 and NI18 is maintained in a floating state.
Impurity region NI14 is connected to an upper-layer metal line (not shown) for voltage signal Voutn through a contact hole C13 formed in interlayer insulating layer ID. Impurity region NI16 is connected to an upper-layer metal line (not shown) for voltage signal Voutp through a contact hole C15 formed in interlayer insulating layer ID.
Impurity regions NI13, NI15 and NI17 are connected to common upper-layer metal line MLB through contact holes C12, C14 and C16 formed in interlayer insulating layer ID, respectively. As a result, impurity regions NI13, NI15 and NI17 have the same voltage Vs. Impurity regions NI13, NI15 and NI17 are connected to an impurity region NI22 in
(Layout of NMOS Transistor MN11)
Referring to
Each of gate electrodes G19 and G22 is connected to upper-layer metal line MLA for supplying ground voltage GND through a contact hole formed in interlayer insulating layer ID. As a result, dummy transistors MND15 and MND16 are turned off.
Gate electrodes G20 and G21 forming the two-finger gate are formed integrally and thereby interconnected, and are connected to an upper-layer metal line (not shown) for supplying bias voltage Vb1 through a contact hole formed in interlayer insulating layer ID. Gate electrodes G20 and G21 may be separated from each other and formed of a polysilicon layer. In this case, each of gate electrodes G20 and G21 is connected individually to the upper-layer metal line (not shown) for supplying bias voltage Vb1.
Impurity regions NI20, NI21, NI23, and NI24 are connected to upper-layer metal line MLA for supplying ground voltage GND through contact holes C22, C23, C25, and C26 formed in interlayer insulating layer ID, respectively. Impurity region NI22 is connected to an upper-layer metal line (not shown) through a contact hole C24 formed in interlayer insulating layer ID, and thereby impurity region NI22 is electrically connected to impurity regions NI13, NI15 and NI17 shown in
Specifically, active region AR11 in
Dummy transistor MND17 includes impurity region NI25 disposed at one end of the one-dimensional arrangement, impurity region NI20 provided adjacent to impurity region NI25, and gate electrode G23 provided between these impurity regions NI25 and NI20. Dummy transistor MND18 includes impurity region NI26 disposed at the other end of the one-dimensional arrangement, impurity region NI24 provided adjacent to impurity region NI26, and gate electrode G24 provided between these impurity regions NI26 and N124.
Each of impurity regions NI25 and NI26 is connected to upper-layer metal line MLA for supplying ground voltage GND through a contact hole formed in the interlayer insulating layer. Gate electrode G23 is formed integrally with gate electrode G19 and is connected to upper-layer metal line MLA through a contact hole formed in the interlayer insulating layer. Gate electrode G24 is formed integrally with gate electrode G22 and is connected to upper-layer metal line MLA through a contact hole formed in the interlayer insulating layer. Gate electrodes G19 and G23 may be separated from each other and formed of a polysilicon layer, or gate electrodes G22 and G24 may be separated from each other and formed of a polysilicon layer. When these gate electrodes are separated and formed individually, each gate electrode is connected individually to upper-layer metal line MLA.
(Layout of PMOS Transistors MP11 and MP12)
As shown in
Gate electrodes G31 and G32 are formed integrally and thereby interconnected, and are connected to an upper-layer metal line MLC for supplying power supply voltage VDD through a contact hole formed in the interlayer insulating layer. Gate electrodes G35 and G36 are formed integrally and thereby interconnected, and are connected to upper-layer metal line MLC through a contact hole formed in the interlayer insulating layer. By fixing voltages of these gate electrodes G31, G32, G35, and G36 to power supply voltage VDD, dummy transistors MPD11 to MPD14 are constantly off. Gate electrodes G31 and G32 may be separated from each other and formed of a polysilicon layer, or gate electrodes G35 and G36 may be separated from each other and formed of a polysilicon layer. In this case, each of gate electrodes G31, G32, G35, and G36 is connected individually to upper-layer metal line MLC.
Gate electrodes G33 and G34 are connected to upper-layer metal lines (not shown) for supplying bias voltages Vb2 and Vb3 through contact holes formed in interlayer insulating layer ID, respectively.
Each of impurity regions PI11, PI14 and PI17 is connected to upper-layer metal line MLC for supplying power supply voltage VDD through a contact hole formed in the interlayer insulating layer. In other words, impurity regions PI11, PI14 and PI17 are configured to be electrically connected to gate electrodes G31, G32, G35, and G36 constantly, and power supply voltage VDD is constantly applied to impurity regions PI11, PI14 and PI17. Since each of impurity regions PI12 and PI16 is not connected to any upper-layer metal lines and power supply voltage VDD is constantly applied to the gate electrodes adjacent to both sides thereof, each of impurity regions PI12 and PI16 is maintained in a floating state.
Impurity region PI13 is connected to an upper-layer metal line (not shown) for voltage signal Voutn through a contact hole formed in the interlayer insulating layer. Impurity region PI15 is connected to an upper-layer metal line (not shown) for voltage signal Voutp through a contact hole formed in the interlayer insulating layer.
Referring to
Each of gate electrodes G31 and G36 is connected to upper-layer metal line MLC for supplying power supply voltage VDD through a contact hole formed in the interlayer insulating layer. As a result, dummy transistors MPD11 and MPD12 are turned off.
Gate electrodes G32 and G33 forming the two-finger gate are formed integrally and thereby interconnected, and are connected to the upper-layer metal line (not shown) for supplying bias voltage Vb2 through a contact hole formed in the interlayer insulating layer. Similarly, gate electrodes G34 and G35 forming the two-finger gate are formed integrally and thereby interconnected, and are connected to the upper-layer metal line (not shown) for supplying bias voltage Vb3 through a contact hole formed in interlayer insulating layer ID. Gate electrodes G32 and G33 may be separated from each other and formed of a polysilicon layer, or gate electrodes G34 and G35 may be separated from each other and formed of a polysilicon layer. In this case, each of gate electrodes G32 and G33 is connected individually to the upper-layer metal line (not shown) for supplying bias voltage Vb2, and each of gate electrodes G34 and G35 is connected individually to the upper-layer metal line (not shown) for supplying bias voltage Vb3.
Each of impurity regions PI11, PI12, PI14, PI16, and PI17 is connected to upper-layer metal line MLC for supplying power supply voltage VDD through a contact hole formed in interlayer insulating layer ID. Impurity region PI13 is connected to the upper-layer metal line (not shown) for voltage signal Voutn through a contact hole formed in interlayer insulating layer ID. Impurity region PI15 is connected to the upper-layer metal line (not shown) for voltage signal Voutp through a contact hole formed in interlayer insulating layer ID.
As already described with reference to
<Second Embodiment>
Referring to
Resistor ladder RLD includes serially-connected resistor elements R(1) to R(M−1) of M−1 in number. Reference potentials VRT and VRB (VRT>VRB) are applied to nodes NDT and NDB at opposing ends of these serially-connected resistor elements R(1) to R(M−1), respectively.
Each of comparators CMP(1) to CMP(M)of M in number includes a differential amplifier AMP and a latch circuit LC that holds a signal outputted from differential amplifier AMP. A non-inverted input terminal of each differential amplifier AMP is connected to input node NIN. An inverted input terminal of differential amplifier AMP provided in the first comparator CMP(1) is connected to node NDT. An inverted input terminal of differential amplifier AMP provided in the M-th comparator CMP(M) is connected to node NDB. An inverted input terminal of differential amplifier AMP provided in the i-th (2≦i ≦M−1) comparator CMP(i) is connected to a node connecting resistor element R(i−1) and resistor element R(i).
Encoder ECD receives data (thermometer code) outputted from comparators CMP(1) to CMP(M) and converts the data into N-bit binary data.
In the flash-type AD converter having the above-described configuration, the same configuration as that of the differential amplifier in the first embodiment described with reference to
NMOS transistors MN12a(2), MN12b(2), MN13a(2), and MN13b(2) as well as dummy transistors MND11(2), MND12(2), MND13(2), and MND14(2) in
Four serially-connected dummy transistors MND13(1), MND14(1), MND12(2), and MND11(2) are provided for element isolation between an impurity region NI17(1) involved in the operation of comparator CMP(1) and an impurity region NI13(2) involved in the operation of comparator CMP(2). Impurity regions NI19(1)/NI11(2) shared by dummy transistors MND14(1) and MND12(2) are connected to upper-layer metal line layer MLA through a contact hole formed in the interlayer insulating layer. As a result, ground voltage GND is applied to impurity regions NI19(1)/NI11(2).
In order to reduce the off-leakage current, two serially-connected dummy transistors are provided between these impurity regions NI19(1)/NI11(2) and impurity region NI17(1) as well as between impurity regions NI19(1)/NI11(2) and impurity region NI13(2). In other words, an impurity region NI18(1), impurity region NI11(2) (NI19(1)) and an impurity region NI12(2) are provided in this order between impurity region NI17(1) included in comparator CMP(1) and impurity region NI13(2) included in comparator CMP(2).
Impurity region NI18(1) is not connected to any upper-layer metal line layers. Moreover, gate electrodes G17(1) and G18(1) provided adjacent to both sides of impurity region NI18(1) are connected to metal line layer MLA, and thereby gate electrodes G17(1) and G18(1) are constantly connected to impurity region NI11(2) and constantly receive ground voltage GND. Therefore, impurity region NI18(1) is maintained in a floating state. Similarly, impurity region NI12(2) is not connected to any upper-layer metal line layers. Moreover, gate electrodes G11(2) and G12(2) provided adjacent to both sides of impurity region NI12(2) are connected to metal line layer MLA, and thereby gate electrodes G11(2) and G12(2) are constantly connected to impurity region NI11(2) and constantly receive ground voltage GND. Therefore, impurity region NI12(2) is maintained in a floating state.
In order to achieve element isolation and reduce the off-leakage current with more reliability, the number of serially-connected dummy transistors may be increased.
In order not to produce the shape nonuniformity caused by the manufacturing process, it is desirable that gate lengths of dummy transistors MND13(1), MND14(1), MND12(2), and MND11(2) be equal to gate lengths of MOS transistors MN13b(1) and MN12a(2) involved in the circuit operation. In other words, gate lengths of gate electrodes G16(1), G17(1), G18(1), G11(2), and G12(2) are equal to one another. Furthermore, it is desirable that lengths, in the gate length direction (arrangement direction of the impurity regions), of impurity regions NI17(1), NI18(1), NI11(2) (NI19(1)), NI12(2), and NI13(2) forming dummy transistors MND13(1), MND14(1), MND12(2), and MND11(2) be all equal.
The NMOS transistors of low threshold voltage used in remaining comparators CMP(3) to CMP(M) in
It should be understood that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.
Reference Signs List
AR active region; G gate electrode; GND ground voltage; ID interlayer insulating layer; MN NMOS transistor; MP PMOS transistor; NI N-type impurity region; PI P-type impurity region; MND N-type dummy transistor; MPD P-type dummy transistor; NC, PC channel region; NW2 N-type well; PSUB P-type semiconductor substrate; PW1, PW11, PW12 P-type well; STI shallow trench isolation; VDD power supply voltage.
Ito, Masao, Deguchi, Kazuaki, Morimoto, Yasuo
Patent | Priority | Assignee | Title |
10680001, | Jun 20 2014 | FLOADIA CORPORATION | Non-volatile semiconductor memory device |
9349727, | Mar 04 2011 | Renesas Electronics Corporation | Semiconductor device |
9842837, | Aug 26 2015 | SK Hynix Inc. | Semiconductor device |
Patent | Priority | Assignee | Title |
5847429, | Jul 31 1995 | Integrated Device Technology, Inc.; Integrated Device Technology, inc | Multiple node ESD devices |
6107659, | Sep 05 1997 | Mitsubishi Denki Kabushiki Kaisha | Nonvolatile semiconductor memory device operable at high speed with low power supply voltage while preventing overerasing/overwriting |
6504763, | Feb 21 2002 | POWERCHIP SEMICONDUCTOR CORP | Nonvolatile semiconductor memory capable of random programming |
6894925, | Jan 14 2003 | Infineon Technologies LLC | Flash memory cell programming method and system |
8067795, | Mar 12 2007 | Texas Instruments Incorporated | Single poly EEPROM without separate control gate nor erase regions |
20030117168, | |||
20050274983, | |||
20060220142, | |||
20070026628, | |||
20070296485, | |||
20080283871, | |||
20080308855, | |||
20100133625, | |||
20110027965, | |||
JP11233640, | |||
JP2003188361, | |||
JP2005353905, | |||
JP2006286889, | |||
JP2007036194, | |||
JP2007329416, | |||
JP2008141101, | |||
JP2008288268, | |||
JP2009267094, | |||
JP4125949, | |||
WO2009037808, |
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